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Every chess player hopes for the opportunity to play a grandmaster some day, and some even dream of defeating one.

The odds on both counts are not especially good. While hundreds of millions of people play chess in person or online, the world chess federation has bestowed the official grandmaster title on fewer than 2,000 players. Canada has just eight active grandmasters.

In pre-pandemic times, the best chance to play a grandmaster might have come in the opening round of a Swiss-system open. Today, its possible to find a game in an online blitz tournament or to challenge a grandmaster during a streaming display.

The other path to playing an elite player is during a simultaneous exhibition, where the grandmaster takes on multiple players at once. Even then, its hard for the average player to make much headway.

My moment in the limelight came in 1997, when I played veteran Israeli grandmaster Leonid Gofshtein in a simultaneous exhibition. He only had eight challengers that day, a small number as some exhibits can include dozens of players.

Somehow I managed to win the game, in just 29 moves. It was a fun moment, but I resisted the urge to turn professional after that.

29. h5, and Black will win material on e4..

Read more here:
Defeating a grandmaster is every chess player's dream - The Globe and Mail

The Herald

Takudzwa Chitsiga Sports Reporter

THE Zimbabwe Chess Federation, in conjunction with Minerva Risk Advisors, will today host the biggest chess competition on the local chess calendar The Minerva Zimbabwe Open Chess Tournament at Joina City in the capital.

The US$10 000 four-day event will run until Monday and has attracted several top players from the Southern African region.

The Minerva Zimbabwe Open Chess Tournament comes just after the conclusion of another national chess competition, the Zimbabwe Easter Open Tournament.

Over 100 local and international participants confirmed their availability for this prestigious event in which the overall winner will walk away US$1 000.

The first edition of the tournament was held in December last year.

Emerald Mushore and Linda Shaba are the defending champions and are expected to be at their best if they are to successfully defend their titles from the invading chess masters from the region.

Zimbabwes highest ranked chess master, International Master Rodwell Makoto, is expected to grace the occasion.

The countrys top rated player in the mens section, Makoto, who is based in South Africa, is expected to lead the local players in this tournament.

The Zimbabwe Chess Federation president, Collin Tongowona, said they are expecting a huge turn out and strong competition.

We are anticipating a very competitive and very exciting chess battles. We havent had a prospect of such an event in the post Covid-19 era. A competition of Minerva Zim Opens magnitude requires international participants to help boost the competitions standards.

We are grateful to Minerva Risk Advisors for the support they continue to render to chess. With such partnerships, chess has a bright future, said Tongowona.

See more here:
Minerva Zim Open Chess tourney begins today - The Herald

SIR - Like everyone else, I feel very sad for the people of Ukraine following the invasion of their country by Vladimir Putin's Russia.

There is no doubt that Putin has waged an illegal war on a sovereign nation and his army have committed war crimes against the people of Ukraine. I agree wholeheartedly with the EU, US and UK efforts to assist Ukraine, with defensive weapons being donated in order to defend themselves against the tyrant, Putin.

Unfortunately, I now fear that Ukraine is being used as a pawn in the longer chess game that involves a regime change in Russia. The allied nations now appear to be upping the ante in order to assist Ukraine in not only defending themselves but now also pushing back and taking the war to Putin.

It`s beginning to look very much like we have effectively declared war with Putin on behalf of Ukraine without the need to become involved in a war on the ground, and the losers in the end will be Ukraine themselves.

Once again, the west appears to be declaring themselves as world Police in order to force other nations to do their bidding. Can we do nothing without a deeper ulterior motive?

Colin Durkin, Moffat Close, Bradford

Excerpt from:
Reader letter: 'Ukraine is a pawn in the longer chess game' - Telegraph and Argus

The Dallas Cowboys did draft Emmitt Smith with the #17 pick so its possible that owner Jerry Jones might capture lightning in a bottle once again. His latest comments suggest hes either playing checkers or 4D chess, or hes being deliberately vague to confuse other teams.

Jerry Jones has owned the Dallas Cowboys for 33 years which means hes overseen 32 or 33 NFL Drafts. And its been 27 years since Dallas won a Super Bowl. So either Jerry doesnt put too much stock in the NFL Draft for stocking up a team or they just havent been able to get it right since they drafted Troy Aikman at #1 overall in 1989.

The Cowboys are expected to address their major needs with their early NFL Draft picks. They currently hold the #24 pick in the 1st round, #56 in the 2nd Round, and #88 in the 3rd Round. After that Dem Boyz have the 129th, 155th, 167th, 176th, 178th, and 193rd picks to try and fix their woes. Mel Kiper Jr. (I know, I know) has them drafting these three with their first three picks: 24. EDGE Arnold Ebiketie, PSU, 56. RT Abraham Lucas, WSU, and 88. WR Bo Melton, Rutgers.

Edge rusher, right tackle, and wide receiver. Jerry Jones on the other hand suggests the team will stay fluid or nimble or pliable or whatever

The replies to that tweet reveal the eternal pessimism that I respect so much from Cowboys fans.

As an unbiased outsider, Id actually really, truly love to know how much input Jerry Jones has on NFL Draft picks in the moment. He says theyll exercise flexibility and that they should be contrarians but are they just hollow words from a guy who has no actual control at the moment because the decisions were made ahead of time or is he gonna hop in there and be like GO GET HIM and pull a total wild card off the board?

For anyone who wants to read more about those Mel Kiper Jr. Mock Draft picks (I know, I know, Mel is irrelevant) just hit that tweet above!

Read more from the original source:
Jerry Jones Is Either Playing Checkers Or 4D Chess Based On Comments - BroBible

Stephen Hawking once suggested Albert Einsteins assertion that God does not play dice with the universe was wrong. In Hawkings view, the discovery of black hole physics confirmed that not only did God play dice, but that he sometimes confuses us by throwing them where they cant be seen.

Are we here by chance or design?

A more pragmatic approach to the question, considering the subject matter, would be to assume that all answers are correct. In fact, thats the basis of quantum physics.

Heres the simplest explanation of how it all works that youll ever read: imagine flipping a coin and then walking away secure in the knowledge that it landed on heads or tails.

If we look at the entire universe and start zooming in until you get down to the tiniest particles, youll see the exact same effect in their interactions. Theyre either going to do one thing or another. And, until you observe them, that potential remains.

With all that potential out there in the universe just waiting to be observed, were able to build quantum computers.

However, like all things quantum, theres a duality involved in harnessing Gods dice for our own human needs. For every mind-blowing feat of quantum engineering we come up with just wait until you read about laser tweezers and time crystals we need some grounded technology to control it.

In reality, theres no such thing as a purely-quantum computer and there probably never will be. Theyre all hybrid quantum-classical systems in one way or another.

Lets start off with why we need quantum computers. Classical (or binary, as theyre often called) computers the kind youre reading this on complete goals by solving tasks.

We program computers to do what we want by giving them a series of commands. If I press the A key on my keyboard, then the computer displays the letter A on my screen.

Somewhere inside the machine, theres code telling it how to interpret the key press and how to display the results.

It took our species approximately 200,000 years to get that far.

In the past century or so, weve come to understand that Newtonian physics doesnt apply to things at very small scales, such as particles, or objects at particularly massive scales such as black holes.

The most useful lesson weve learned in our relatively recent study of quantum physics is that particles can become entangled.

Quantum computers allow us to harness the power of entanglement. Instead of waiting for one command to execute, as binary computers do, quantum computers can come to all of their conclusions at once. In essence, theyre able to come up with (nearly) all the possible answers at the same time.

The main benefit to this is time. A simulation or optimization task that might take a supercomputer a month to process could be completed in mere seconds on a quantum computer.

The most commonly cited example of this is drug discovery.In order to create new drugs, scientists have to study their chemical interactions. Its a lot like looking for a needle in a never-ending field of haystacks.

There are near-infinite possible chemical combinations in the universe, sorting out their individual combined chemical reactions is a task no supercomputer can do within a useful amount of time.

Quantum computing promises to accelerate these kinds of tasks and make previously impossible computations commonplace.

But it takes more than just expensive, cutting-edge hardware to produce these ultra-fast outputs.

Hybrid quantum computing systems integrate classical computing platforms and software with quantum algorithms and simulations.

And, because theyre ridiculously expensive and mostly experimental, theyre almost exclusively accessed via cloud connectivity.

In fact, theres a whole suite of quantum technologies out there aside from hybrid quantum computers, though theyre the technology that gets the most attention.

In a recent interview with Neural, the CEO of SandboxAQ (a Google sibling company under the Alphabet umbrella), Jack Hidary, lamented:

For whatever reason, the mainstream media seems to only focus on quantum computing.

There are also quantum sensing, quantum communications, quantum imaging, and quantum simulations although, some of those overlap with quantum hybrid computing as well.

The point is, as Hidary also told Neural, were at an inflection point. Quantum tech is no longer a far-future technology. Its here in many forms today.

But the scope of this article is limited to hybrid quantum computing technologies. And, for that, were focused on two things:

There are two kinds of problems in the quantum computing world: optimization problems and the kind that arent optimization problems.

For the former, you need a quantum annealing system. And, for everything else, you need a gate-based quantum computer probably. Those are still very much in the early stages of development.

But companies such as D-Wave have been building quantum annealing systems for decades.

Heres how D-Wave describes the annealing process:

The systems starts with a set of qubits, each in a superposition state of 0 and 1. They are not yet coupled. When they undergo quantum annealing, the couplers and biases are introduced and the qubits become entangled. At this point, the system is in an entangled state of many possible answers. By the end of the anneal, each qubit is in a classical state that represents the minimum energy state of the problem, or one very close to it.

Heres how we describe it here at Neural: have you ever seen one of those 3-D pin art sculpture things?

Thats pretty much what the annealing process is. The pin art sculpture thing is the computer and your hand is the annealing process. Whats left behind is the minimum energy state of the problem.

Gate-based quantum computers, on the other hand, function entirely differently. Theyre incredibly complex and there are a number of different ways to implement them but, essentially, they run algorithms.

These include Microsofts new cutting-edge experimental system which, according to a recent blog post, is almost ready for prime time:

Microsofts approach has been to pursue a topological qubit that has built-in protection from environmental noise, which means it should take far fewer qubits to perform useful computation and correct errors. Topological qubits should also be able to process information quickly, and one can fit more than a million on a wafer thats smaller than the security chip on a credit card.

And even the most casual of science readers have probably heard about Googles amazing time crystal breakthrough.

Last year, here on Neural, I wrote:

Googles time crystals could be the greatest scientific achievement of our lifetimes.

A time crystal is a new phase of matter that, simplified, would be like having a snowflake that constantly cycled back and forth between two different configurations. Its a seven-pointed lattice one moment and a ten-pointed lattice the next, or whatever.

Whats amazing about time crystals is that when they cycle back and forth between two different configurations, they dont lose or use any energy.

Heck, even D-Wave, the company that put quantum annealing on the map, has plans to introduce cross-platform hybrid quantum computing to the masses with an upcoming gate-based model of its own.

The quantum computing industry is already thriving. As far as were concerned here at Neural, the mainstream is just now starting to catch a whiff of what the 2030s are going to look like.

As Bob Wisnieff, CTO of IBM Quantum, told Neural back in 2019 when IBM unveiled its first commercial quantum system:

We get to be in the right place at the right time for quantum computing, this is a joy project This design represents a pivotal moment in tech.

According to Wisnieff and others building the hybrid quantum computer systems of tomorrow, the timeline from experimental to fully-implemented is very short.

Where annealing and similar quantum optimization systems have been around for years, were now seeing the first generation of gate-based models of quantum advantage come to market.

You might remember reading about quantum supremacy a few years back. Quantum advantage is the same thing but, semantically speaking, its a bit more accurate. Both terms represent the point at which a quantum computer can perform a given function in a reasonable amount of time that would take a classical computer too long to do.

The reason supremacy quickly went out of favor is because quantum computers rely on classical computers to perform these functions, so it makes more sense to say they give an advantage when used in tandem. Thats the very definition of hybrid quantum computing.

As for whats next? Its unlikely youll see a ticker-tape parade for quantum computing any time soon. There wont be an iPhone of quantum computers, or a cultural zeitgeist surrounding the launch of a particular processor.

Instead, like all great things in science, over the course of the next five, 10, 100, and 1,000 years, scientists and engineers will continue to pass the baton from one generation to the next as they stand upon the shoulders of giants to see into the future.

Thanks to their continuing work, in our lifetimes were likely to see vast improvements to power grids, a resolution to mass scheduling conflicts, dynamic shipping optimizations, pitch-perfect quantum chemistry simulations, and even the first inklings of far-future tech such as warp engines.

These technological advances will improve our quality of life, extend our lives, and help us to reverse human-caused climate change.

Hybrid quantum computing is, in our humble opinion here at Neural, the single most important technology humankind has ever endeavored to develop. We hope youll stick with us as we continue to blaze a trail of coverage at the frontier of this new and exciting realm of engineering.

See the original post:
A regular person's guide to the mind-blowing world of hybrid quantum computing - The Next Web